Implementation method for eliminating harmful algal blooms through optimized utilization of modified clays

ABSTRACT

A method for eliminating harmful algal blooms through optimized utilization of a modified clay method includes building a real-time state index and a standardized value grading system for eliminating a site harmful algal bloom or a harmful algal bloom in accordance with the features of monitored harmful algal bloom organisms and modified clay flocculates; acquiring corresponding grade codes of feature index values of the harmful algal bloom in a to-be-treated water body or harmful algal bloom elimination effect through the real-time site state index and the standardized value grading system; comparing the above grade codes with an expert system to obtain an operation solution for eliminating harmful algal blooms through optimized utilization of the modified clay method. The result is tracked and monitored in real time and the operation solution is optimized and adjusted in time according to the harmful algal bloom elimination effect.

CROSS-REFERENCE TO RELATED APPLICATIONS

The instant application is a continuation-in-part application of PCT international application No. PCT/CN2017/106623, filed on Oct. 18, 2017, which claims the benefit of the Chinese patent application No. CN201611191048.0, filed on Dec. 21, 2016, the entire disclosures of which are hereby incorporated by reference.

TECHNICAL FIELD

The present invention relates to the field of treating harmful algal blooms in a water environment, and particularly relates to an implementation method for eliminating harmful algal blooms through optimized utilization of modified clays.

BACKGROUND

In recent decades, harmful algal blooms (HABs) occur frequently in coastal waters, estuaries and other sensitive waters. Some poisonous and harmful algal blooms seriously influence the water quality and ecological safety, and even may directly endanger resident health. To protect the safety of the coastal environment and guarantee the healthy development of marine economy especially in some water conservation areas, culture zones, scenic spots and other sensitive waters threatened or directly affected by HABs, some counter-measures which can reduce or eliminate the hazard of HABs are urgently needed.

The modified clay method is patented technology for treating HABs. The basic principle of this technology is to aggregate bloomed algal cells by modified clay particles to form bigger particles which then subside by gravity and separate from the above water body, so as to remove the redundant bloomed algae. The treatment of HABs by the modified clay method has been improved and widely applied in the last decade. Recently, in different waters from north to south in China, there are many implementation cases in which modified clays have been applied successfully to control harmful algal blooms. Therefore, the modified clay method is considered to be the most effective and feasible counter-measure for HABs control, and receives extensive attention both in China and abroad. When the modified clay method is used for prevention and control of HABs, usually a slurry of the modified clay is pre-mixed and then sprinkled to the surface of the water body in which harmful algal bloom occurs. The modified clay particles are quickly flocculated with the bloomed algal cells and settle together so as to eliminate the excessive harmful algae. Because HABs often influence large-area waters when they outbreak, to rapidly and effectively control the dispersal of the bloomed algae, mechanized equipment operation is more effective means. Patent CN101229933 invented a device which is independent of additional motorized mixer and can be easily used to carry out the field work of the modified clay sprinkling. Patent ZL201520279270.0 provided a compositive device which can finish the whole processes of HAB treated with the modified clays. All these invented technologies aimed to promote the mechanization of field works for treating HABs.

However, the complexity and variability of HABs bring many challenges to the engineering application of the modified clay. Due to the joint effects of biological and physical influences, some bloomed algae often in homogenously scatter in the field water. Because the flocculation efficiency between the modified clay and the HAB organism is one of the key processes which determine the algal removal efficiency, the sprinkling operation manners must be adjusted frequently to bring about efficient flocculation. At present, the field application is still manually adopted for the wide range of HABs, which needs high labor power and costs high dosage of the modified clay, but only brings unsatisfactory removal efficiency. In order to ensure the effectiveness and accuracy of treatment, there is an urgent need to build a set of scientific and workable field implementation method to ease the field application and save the input of materials and manpower.

SUMMARY

The purpose of the present invention is to provide an implementation method for eliminating harmful algal blooms through optimized utilization of modified clays.

To achieve the above purpose, the present invention adopts the following technical solution:

An implementation method for eliminating harmful algal blooms through optimized utilization of modified clays is as follows:

1) building a real-time state index of algae and floc particles formed between algae and modified clays and a standardized value grading system for HAB treatment in accordance with the features of blooms and flocculation monitored in field (see Table 1);

2) obtaining the corresponding grade code which denotes the field algal bloom state by checking a standardized value grading system according to the state index values;

3) comparing the above grade code with an expert system (see Table 2) to obtain an optimized operation solution for HAB treatment with the modified clays (see Table 3).

After 20-30 min when a field operation is implemented in accordance with the introduced solution obtained by above programme, the chlorophyll fluorescence and the floc size in the treated water are determined. The preliminary effectiveness of treatment is judged according to the change of the chlorophyll fluorescence. If the chlorophyll fluorescence value is reduced by more than 15%, the field operation is continuously implemented in accordance with the introduced operation solution until the removal efficiency is less than 15%. If the chlorophyll fluorescence value is reduced by less than 15%, it means that the introduced operation solution is not ideally effective and a new solution should be chosen according to the real-time observation result using the above expert system again.

The above real-time optimized operation solution for bloomed water treatment is based on the rapid and continuous data acquisition of the relevant characteristics of the HAB-causing organisms and the modified clay flocs in water by some physical, chemical or biologic method. The acquisition methods may be off-line sample analysis or on-line continuous measurement, while on-line continuous measurement is preferred.

The above expert system is composed of three parts, i.e. HABs characteristics, modified clay floc features and operation solution for sprinkling modified clay. The HABs characteristics consist of the HAB species, distribution, strength, density, etc. The modified clay floc features consist of size distribution and concentration of the flocs formed between the bloomed algae and the modified clay particles. The operation solution is an integrated operation technology of the modified clay sprinkling which gives details for the sprinkling manners, concentration, frequency, etc.

The real-time state index and the standardized value grading system are designed by grading the index values after calculating the values of all indices of the HAB and the modified clay flocs in water. The HAB indices comprise seriousness, distribution characteristics, cell morphology, cell size, and motion capability of bloomed organisms; and the feature of the modified clay flocs is represented by the grain size of the modified clay flocs (see Table 1).

The HAB seriousness is graded into low, medium and high and their corresponding codes are L, M and H, wherein low seriousness means that the chl.a concentration given by the fluorescence of the bloomed water is less than 15 ug/L; medium seriousness means that the chl.a concentration given by the fluorescence of the bloomed water is 15-30 μg/L; high seriousness means that the chl.a concentration given by the fluorescence of the water is greater than 30 μg/L;

the HABs distribution characteristics are classified into three types, i.e. fragmentary dispersion, strip type, dense cover, with corresponding codes of D, C and G respectively. HABs usually behave differently according to the local water current or tide;

the cell morphology of the bloomed organisms are divided into spherical or non-spherical forms, with the corresponding codes of S and N. The spherical or subsphaeroidal shape is dominant in bloomed species. If there are hard bulges or subsidiary organelle on the cell outside but their sizes to the cell in diameter is less than ½, the organism is thought as sphere. Otherwise, the organism is thought as non-spherical cell;

the cell size of algae are divided into small, medium and large, and corresponding codes are L, M and N, wherein small size means that the cell diameter of the organism is less than 15 μm; medium size means that the cell diameter of the organism is 15-100 μm; and large size means that the cell diameter of the organism is greater than 100 um;

the motion capability of the organisms is divided into low, medium and high, and corresponding codes are L, M and H, wherein low capability means that the organism does not have motion capability and is suspended under the action of the water flow, etc.; medium capability means that the organism does not have motion capability but is suspended due to phototaxis or has weak buoyant capability; high capability means that the harmful algal bloom organism has strong buoyant capability;

the grain sizes of the modified clay flocs are divided into small, medium and large, and corresponding codes are L, M and H, wherein small grain size means that the median particle size (D50) is less than the cell diameter of the organism; medium grain size means that the median particle size (D50) is 1-5 times of the cell diameter of the organism; and large grain size means that the median particle size (D50) is more than 5 times of the cell diameter of the organism.

The above mentioned characteristics of the organisms can be used to describe or measure the size and density of the bloomed algae, as well as the distribution styles of the occurred HABs, such as water mass type, dispersion type, etc. The common measuring methods include a fluorescence method, a counting method, a spectrophotometric method, chromatography, etc. to quickly acquire the features of the bloomed organisms in the water, such as the size and density, as well as distribution styles of the occurred HABs. The features of the algae are observed preferably based on the on-line in vivo fluorescence method.

The above features of the modified clay flocs can be analyzed by particle size, concentration, etc. The common measuring methods include the optical online monitoring methods, micrographic methods, gravimetric methods, etc. to quickly acquire morphology features of the flocs, such as the particle size, particle concentration, particle size distribution, etc. An on-line laser light scattering method is preferred.

The order of corresponding grade codes is consistent with the order of the determined feature indexes of the HAB and the modified clay flocs.

The operation solution achieves the purpose of optimizing the effect by adjusting the sprinkling modes, density, frequency, etc. of the modified clay, wherein the sprinkling modes include raining type, pouring type, ploughing type, etc., and the raining type is preferred; the sprinkling density is a proportion of the modified clay powder with seawater in a slurry which is selected in field and obtained by premixing the powder with seawater before sprinkling onto the bloomed water surface; and the sprinkling frequency means duration time, an interval and sprinkling number of times when operation at the same site.

TABLE 1 Real-Time Site State Index and Standardized Value Grading Table Feature Index Features of Harmful algal blooms or Flocs Grades Codes HAB chl.a concentration given by the fluorescence of the Low L seriousness bloomed water is less than 15 μg/L chl.a concentration given by the fluorescence of the Medium M bloomed water is 15-30 μg/L chl.a concentration given by the fluorescence of the High H bloomed water is greater than 30 μg/L HAB HAB presents fragmentary dispersion in a target sea D distribution area features HAB presents strip type and moves with water flow C or tides HAB presents dense cover in a target sea area with G insufficient flow of water flows Individual Dominant organism cells of the HAB are spherical or Spherical S forms of the subsphaeroidal; no hard bulge or hard subsidiary bloomed organelle with a cell diameter that is greater than ½ organisms exists on the periphery Dominant organism cells of the HAB have forms Non- N beyond the above spherical or subsphaeroidal forms spherical Individual Cell diameter of the bloomed organism is less than Small L sizes of the 15 μm bloomed Cell diameter of the bloomed organism is 15-100 μm Medium M organisms Cell diameter of the bloomed organism is greater Large H than 100 μm Motion The bloomed organism does not have motion Low L capability of capability and is suspended under the action of the bloomed water flow, etc organisms The bloomed organism does not have motion Medium M capability but is suspended due to phototaxisor has weak buoyant capability The bloomed organism has strong buoyant capability High H Particle size of The median particle size (D50) is less than the cell Small L modified clay diameter of the bloomed organism flocs The median particle size (D50) is 1-5 times of the Medium M cell diameter of the bloomed organism The median particle size (D50) is more than 5 times Large H of the cell diameter of the bloomed organism

TABLE 2 Expert Cognition and Decision Table for Eliminating Harmful algal blooms through Modified Clay Method Harmful algal bloom features Adjustment of Operation Solution Based Proposed on Features of Flocculate Distribution Individual Individual Motion operation Particle Alternative Alternative No. Codes Seriousness features forms sizes capability solution size solution 1 solution 2 001 BLDSSL Low Fragmentary Spherical Small Low CHLM Small CHLH CHMH dispersion 002 BLDSSL Low Fragmentary Spherical Small Low CHLM Medium CHMM CHHM dispersion 003 BLDSSL Low Fragmentary Spherical Small Low CHLM Large CHML CHHM dispersion 004 BLDSLM Low Fragmentary Spherical Small Medium CHMM Small CHMH CHMH dispersion 005 BLDSLM Low Fragmentary Spherical Small Medium CHMM Medium CHHM CHHH dispersion 006 BLDSLM Low Fragmentary Spherical Small Medium CHMM Large CHML CHHL dispersion 007 BLDSLH Low Fragmentary Spherical Small High CHHM Small CHHH CHHH dispersion 008 BLDSLH Low Fragmentary Spherical Small High CHHM Medium CHHH CHHH dispersion 009 BLDSLH Low Fragmentary Spherical Small High CHHM Large CHHH CHHH dispersion 010 BLDSML Low Fragmentary Spherical Medium Low CHLM Small CHLH CHMH dispersion 011 BLDSML Low Fragmentary Spherical Medium Low CHLM Medium CHMM CHHM dispersion 012 BLDSML Low Fragmentary Spherical Medium Low CHLM Large CHML CHMM dispersion 013 BLDSMM Low Fragmentary Spherical Medium Medium CHMM Small CHMH CHHH dispersion 014 BLDSMM Low Fragmentary Spherical Medium Medium CHMM Medium CHHM CHHH dispersion 015 BLDSMM Low Fragmentary Spherical Medium Medium CHMM Large CHHL CHHM dispersion 016 BLDSMH Low Fragmentary Spherical Medium High CHHM Small CHHH CHHH dispersion 017 BLDSMH Low Fragmentary Spherical Medium High CHHM Medium CHHH CHHH dispersion 018 BLDSMH Low Fragmentary Spherical Medium High CHHM Large CHHL CHHL dispersion 019 BLDSHL Low Fragmentary Spherical Large Low CHLL Small CHLM CHMM dispersion 020 BLDSHL Low Fragmentary Spherical Large Low CHLL Medium CHML CHMM dispersion 021 BLDSHL Low Fragmentary Spherical Large Low CHLL Large CHLL CHLL dispersion 022 BLDSHM Low Fragmentary Spherical Large Medium CHML Small CHMM CHHM dispersion 023 BLDSHM Low Fragmentary Spherical Large Medium CHML Medium CHHL CHMM dispersion 024 BLDSHM Low Fragmentary Spherical Large Medium CHML Large CHLL CHLL dispersion 025 BLDSHH Low Fragmentary Spherical Large High CHHL Small CHMM CHHM dispersion 026 BLDSHH Low Fragmentary Spherical Large High CHHL Medium CHHM CHHM dispersion 027 BLDSHH Low Fragmentary Spherical Large High CHHL Large CHML CHLL dispersion 028 BLDNLL Low Fragmentary Non- Small Low CHLL Small CHLM CHMM dispersion spherical 029 BLDNLL Low Fragmentary Non- Small Low CHLL Medium CHML CHMM dispersion spherical 030 BLDNLL Low Fragmentary Non- Small Low CHLL Large CHLL CHLL dispersion spherical 031 BLDNLM Low Fragmentary Non- Small Medium CHML Small CHMM CHHM dispersion spherical 032 BLDNLM Low Fragmentary Non- Small Medium CHML Medium CHMM CHHM dispersion spherical 033 BLDNLM Low Fragmentary Non- Small Medium CHML Large CHLL CHLL dispersion spherical 034 BLDNLH Low Fragmentary Non- Small High CHMM Small CHMH CHHH dispersion spherical 035 BLDNLH Low Fragmentary Non- Small High CHMM Medium CHHM CHHM dispersion spherical 036 BLDNLH Low Fragmentary Non- Small High CHMM Large CHML CHLL dispersion spherical 037 BLDNML Low Fragmentary Non- Medium Low CHLL Small CHLM CHMM dispersion spherical 038 BLDNML Low Fragmentary Non- Medium Low CHLL Medium CHLM CHMM dispersion spherical 039 BLDNML Low Fragmentary Non- Medium Low CHLL Large CHLL CHLL dispersion spherical 040 BLDNMM Low Fragmentary Non- Medium Medium CHLM Small CHLH CHMH dispersion spherical 041 BLDNMM Low Fragmentary Non- Medium Medium CHLM Medium CHMM CHMH dispersion spherical 042 BLDNMM Low Fragmentary Non- Medium Medium CHLM Large CHLL CHLL dispersion spherical 043 BLDNMH Low Fragmentary Non- Medium High CHMH Small CHHH CHHH dispersion spherical 044 BLDNMH Low Fragmentary Non- Medium High CHMH Medium CHHH CHHH dispersion spherical 045 BLDNMH Low Fragmentary Non- Medium High CHMH Large CHMM CHML dispersion spherical 046 BLDNHL Low Fragmentary Non- Large Low CHLL Small CHLM CHMM dispersion spherical 047 BLDNHL Low Fragmentary Non- Large Low CHLL Medium CHML CHMM dispersion spherical 048 BLDNHL Low Fragmentary Non- Large Low CHLL Large CHLL CHLM dispersion spherical 049 BLDNHM Low Fragmentary Non- Large Medium CHML Small CHMM CHHM dispersion spherical 050 BLDNHM Low Fragmentary Non- Large Medium CHML Medium CHMM CHHM dispersion spherical 051 BLDNHM Low Fragmentary Non- Large Medium CHML Large CHLL CHLL dispersion spherical 052 BLDNHH Low Fragmentary Non- Large High CHHL Small CHHM CHMH dispersion spherical 053 BLDNHH Low Fragmentary Non- Large High CHHL Medium CHMM CHHM dispersion spherical 054 BLDNHH Low Fragmentary Non- Large High CHHL Large CHML CHMM dispersion spherical 055 BLCSLL Low Strip type Spherical Small Low CPLM Small CPLH CPMM 056 BLCSLL Low Strip type Spherical Small Low CPLM Medium CPMM CPMH 057 BLCSLL Low Strip type Spherical Small Low CPLM Large CPLL CPML 058 BLCSLM Low Strip type Spherical Small Medium CPHM Small CPHH CPHH 059 BLCSLM Low Strip type Spherical Small Medium CPHM Medium CPHH CPHH 060 BLCSLM Low Strip type Spherical Small Medium CPHM Large CPHL CPHH 061 BLCSLH Low Strip type Spherical Small High CPMH Small CPHH CPHH 062 BLCSLH Low Strip type Spherical Small High CPMH Medium CPHH CPHH 063 BLCSLH Low Strip type Spherical Small High CPMH Large CPMM CPHM 064 BLCSML Low Strip type Spherical Medium Low CPLM Small CPLH CPMH 065 BLCSML Low Strip type Spherical Medium Low CPLM Medium CPMM CPHM 066 BLCSML Low Strip type Spherical Medium Low CPLM Large CPLL CPML 067 BLCSMM Low Strip type Spherical Medium Medium CPMM Small CPMH CPHH 068 BLCSMM Low Strip type Spherical Medium Medium CPMM Medium CPHM CPHH 069 BLCSMM Low Strip type Spherical Medium Medium CPMM Large CPML CPHL 070 BLCSMH Low Strip type Spherical Medium High CPHM Small CPHH CPHH 071 BLCSMH Low Strip type Spherical Medium High CPHM Medium CPHH CPHH 072 BLCSMH Low Strip type Spherical Medium High CPHM Large CPMM CPHL 073 BLCSHL Low Strip type Spherical Large Low CPLM Small CPLH CPMM 074 BLCSHL Low Strip type Spherical Large Low CPLM Medium CPMM CPMH 075 BLCSHL Low Strip type Spherical Large Low CPLM Large CPLL CPML 076 BLCSHM Low Strip type Spherical Large Medium CPHL Small CPHM CPMM 077 BLCSHM Low Strip type Spherical Large Medium CPHL Medium CPMM CPHM 078 BLCSHM Low Strip type Spherical Large Medium CPHL Large CPML CPLL 079 BLCSHH Low Strip type Spherical Large High CPHL Small CPMM CPMH 080 BLCSHH Low Strip type Spherical Large High CPHL Medium CPHM CPMM 081 BLCSHH Low Strip type Spherical Large High CPHL Large CPML CPLL 082 BLCNLL Low Strip type Non- Small Low CPLL Small CPLM CPMM spherical 083 BLCNLL Low Strip type Non- Small Low CPLL Medium CPML CPMM spherical 084 BLCNLL Low Strip type Non- Small Low CPLL Large CPML CPHL spherical 085 BLCNLM Low Strip type Non- Small Medium CPLM Small CPLH CPMH spherical 086 BLCNLM Low Strip type Non- Small Medium CPLM Medium CPMM CPHM spherical 087 BLCNLM Low Strip type Non- Small Medium CPLM Large CPML CPHL spherical 088 BLCNLH Low Strip type Non- Small High CPLH Small CPMH CPHH spherical 089 BLCNLH Low Strip type Non- Small High CPLH Medium CPMH CPHH spherical 090 BLCNLH Low Strip type Non- Small High CPLH Large CPMM CPHM spherical 091 BLCNML Low Strip type Non- Medium Low CPLL Small CPLM CPMM spherical 092 BLCNML Low Strip type Non- Medium Low CPLL Medium CPML CPMM spherical 093 BLCNML Low Strip type Non- Medium Low CPLL Large CPML CPML spherical 094 BLCNMM Low Strip type Non- Medium Medium CPLM Small CPLH CPMH spherical 095 BLCNMM Low Strip type Non- Medium Medium CPLM Medium CPMM CPMH spherical 096 BLCNMM Low Strip type Non- Medium Medium CPLM Large CPML CPHL spherical 097 BLCNMH Low Strip type Non- Medium High CPLH Small CPLM CPMH spherical 098 BLCNMH Low Strip type Non- Medium High CPLH Medium CPMH CPMM spherical 099 BLCNMH Low Strip type Non- Medium High CPLH Large CPML CPMM spherical 100 BLCNHL Low Strip type Non- Large Low CPLL Small CPMM CPMH spherical 101 BLCNHL Low Strip type Non- Large Low CPLL Medium CPMM CPMH spherical 102 BLCNHL Low Strip type Non- Large Low CPLL Large CPML CPHL spherical 103 BLCNHM Low Strip type Non- Large Medium CPLM Small CPLH CPMH spherical 104 BLCNHM Low Strip type Non- Large Medium CPLM Medium CPMM CPHM spherical 105 BLCNHM Low Strip type Non- Large Medium CPLM Large CPML CPMM spherical 106 BLCNHH Low Strip type Non- Large High CPLH Small CPMH CPHH spherical 107 BLCNHH Low Strip type Non- Large High CPLH Medium CPMH CPHH spherical 108 BLCNHH Low Strip type Non- Large High CPLH Large CPMH CPHM spherical 109 BLGSLL Low Dense cover Spherical Small Low CFLH Small CFLM CFMM 110 BLGSLL Low Dense cover Spherical Small Low CFLH Medium CFMH CFHH 111 BLGSLL Low Dense cover Spherical Small Low CFLH Large CFMM CFHM 112 BLGSLM Low Dense cover Spherical Small Medium CFMH Small CFHH CFHH 113 BLGSLM Low Dense cover Spherical Small Medium CFMH Medium CFHH CFHH 114 BLGSLM Low Dense cover Spherical Small Medium CFMH Large CFMM CFHM 115 BLGSLH Low Dense cover Spherical Small High CFHH Small CFHH CFHH 116 BLGSLH Low Dense cover Spherical Small High CFHH Medium CFHH CFHH 117 BLGSLH Low Dense cover Spherical Small High CFHH Large CFHM CFHL 118 BLGSML Low Dense cover Spherical Medium Low CFLM Small CFMM CFHM 119 BLGSML Low Dense cover Spherical Medium Low CFLM Medium CFMM CFMH 120 BLGSML Low Dense cover Spherical Medium Low CFLM Large CFMM CFML 121 BLGSMM Low Dense cover Spherical Medium Medium CFMM Small CFMH CFHH 122 BLGSMM Low Dense cover Spherical Medium Medium CFMM Medium CFHM CFHH 123 BLGSMM Low Dense cover Spherical Medium Medium CFMM Large CFHL CFHM 124 BLGSMH Low Dense cover Spherical Medium High CFHM Small CFHH CFHH 125 BLGSMH Low Dense cover Spherical Medium High CFHM Medium CFHH CFHH 126 BLGSMH Low Dense cover Spherical Medium High CFHM Large CFML CFHL 127 BLGSHL Low Dense cover Spherical Large Low CFLM Small CFLH CFMH 128 BLGSHL Low Dense cover Spherical Large Low CFLM Medium CFMM CFHM 129 BLGSHL Low Dense cover Spherical Large Low CFLM Large CFML CFHL 130 BLGSHM Low Dense cover Spherical Large Medium CFHL Small CFHM CFHH 131 BLGSHM Low Dense cover Spherical Large Medium CFHL Medium CFHM CFHH 132 BLGSHM Low Dense cover Spherical Large Medium CFHL Large CFML CFLL 133 BLGSHH Low Dense cover Spherical Large High CFHL Small CFHM CFHH 134 BLGSHH Low Dense cover Spherical Large High CFHL Medium CFHM CFHH 135 BLGSHH Low Dense cover Spherical Large High CFHL Large CFML CFLL 136 BLGNLL Low Dense cover Non- Small Low CFLL Small CFLM CFMH spherical 137 BLGNLL Low Dense cover Non- Small Low CFLL Medium CFMM CFHM spherical 138 BLGNLL Low Dense cover Non- Small Low CFLL Large CFML CFHL spherical 139 BLGNLM Low Dense cover Non- Small Medium CFLM Small CFLH CFMH spherical 140 BLGNLM Low Dense cover Non- Small Medium CFLM Medium CFML CFMM spherical 141 BLGNLM Low Dense cover Non- Small Medium CFLM Large CFML CFHL spherical 142 BLGNLH Low Dense cover Non- Small High CFLH Small CFMH CFHH spherical 143 BLGNLH Low Dense cover Non- Small High CFLH Medium CFMH CFMM spherical 144 BLGNLH Low Dense cover Non- Small High CFLH Large CFMM CFML spherical 145 BLGNML Low Dense cover Non- Medium Low CFLL Small CFLM CFMH spherical 146 BLGNML Low Dense cover Non- Medium Low CFLL Medium CFML CFMM spherical 147 BLGNML Low Dense cover Non- Medium Low CFLL Large CFML CFHL spherical 148 BLGNMM Low Dense cover Non- Medium Medium CFLM Small CFLH CFMH spherical 149 BLGNMM Low Dense cover Non- Medium Medium CFLM Medium CFMM CFMH spherical 150 BLGNMM Low Dense cover Non- Medium Medium CFLM Large CFLL CFML spherical 151 BLGNMH Low Dense cover Non- Medium High CFLH Small CFMH CFHH spherical 152 BLGNMH Low Dense cover Non- Medium High CFLH Medium CFMH CFHH spherical 153 BLGNMH Low Dense cover Non- Medium High CFLH Large CFML CFHL spherical 154 BLGNHL Low Dense cover Non- Large Low CFLL Small CFLM CFMM spherical 155 BLGNHL Low Dense cover Non- Large Low CFLL Medium CFLM CFMM spherical 156 BLGNHL Low Dense cover Non- Large Low CFLL Large CFML CFML spherical 157 BLGNHM Low Dense cover Non- Large Medium CFLM Small CFLH CFMH spherical 158 BLGNHM Low Dense cover Non- Large Medium CFLM Medium CFMM CFHM spherical 159 BLGNHM Low Dense cover Non- Large Medium CFLM Large CFLL CFML spherical 160 BLGNHH Low Dense cover Non- Large High CFLH Small CFMH CFHH spherical 161 BLGNHH Low Dense cover Non- Large High CFLH Medium CFMH CFHH spherical 162 BLGNHH Low Dense cover Non- Large High CFLH Large CFLM CFMM spherical 163 BMDSLL Medium Fragmentary Spherical Small Low CHLM Small CHLH CHMH dispersion 164 BMDSLL Medium Fragmentary Spherical Small Low CHLM Medium CHMM CHHM dispersion 165 BMDSLL Medium Fragmentary Spherical Small Low CHLM Large CHML CHHL dispersion 166 BMDSLM Medium Fragmentary Spherical Small Medium CHMM Small CHMH CHHH dispersion 167 BMDSLM Medium Fragmentary Spherical Small Medium CHMM Medium CHHM CHHH dispersion 168 BMDSLM Medium Fragmentary Spherical Small Medium CHMM Large CHML CHLL dispersion 169 BMDSLH Medium Fragmentary Spherical Small High CHHM Small CHHH CHHH dispersion 170 BMDSLH Medium Fragmentary Spherical Small High CHHM Medium CHHH CHHH dispersion 171 BMDSLH Medium Fragmentary Spherical Small High CHHM Large CHML CHMM dispersion 172 BMDSML Medium Fragmentary Spherical Medium Low CHLM Small CHLH CHMH dispersion 173 BMDSML Medium Fragmentary Spherical Medium Low CHLM Medium CHMM CHHM dispersion 174 BMDSML Medium Fragmentary Spherical Medium Low CHLM Large CHLL CHML dispersion 175 BMDSMM Medium Fragmentary Spherical Medium Medium CHMM Small CHMH CHHH dispersion 176 BMDSMM Medium Fragmentary Spherical Medium Medium CHMM Medium CHHM CHHH dispersion 177 BMDSMM Medium Fragmentary Spherical Medium Medium CHMM Large CHML CHLL dispersion 178 BMDSMH Medium Fragmentary Spherical Medium High CHHM Small CHHH CHHH dispersion 179 BMDSMH Medium Fragmentary Spherical Medium High CHHM Medium CHHH CHHH dispersion 180 BMDSMH Medium Fragmentary Spherical Medium High CHHM Large CHHL CHML dispersion 181 BMDSHL Medium Fragmentary Spherical Large Low CHLL Small CHLM CHMM dispersion 182 BMDSHL Medium Fragmentary Spherical Large Low CHLL Medium CHLM CHMM dispersion 183 BMDSHL Medium Fragmentary Spherical Large Low CHLL Large CHML CHHL dispersion 184 BMDSHM Medium Fragmentary Spherical Large Medium CHML Small CHMM CHMH dispersion 185 BMDSHM Medium Fragmentary Spherical Large Medium CHML Medium CHMM CHHM dispersion 186 BMDSHM Medium Fragmentary Spherical Large Medium CHML Large CHHL CHLL dispersion 187 BMDSHH Medium Fragmentary Spherical Large High CHHL Small CHHM CHHH dispersion 188 BMDSHH Medium Fragmentary Spherical Large High CHHL Medium CHHM CHHH dispersion 189 BMDSHH Medium Fragmentary Spherical Large High CHHL Large CHML CHLL dispersion 190 BMDNLL Medium Fragmentary Non- Small Low CHLL Small CHLH CHMM dispersion spherical 191 BMDNLL Medium Fragmentary Non- Small Low CHLL Medium CHLM CHMM dispersion spherical 192 BMDNLL Medium Fragmentary Non- Small Low CHLL Large CHML CHHL dispersion spherical 193 BMDNLM Medium Fragmentary Non- Small Medium CHML Small CHMM CHMH dispersion spherical 194 BMDNLM Medium Fragmentary Non- Small Medium CHML Medium CHMM CHHM dispersion spherical 195 BMDNLM Medium Fragmentary Non- Small Medium CHML Large CHHL CHLL dispersion spherical 196 BMDNLH Medium Fragmentary Non- Small High CHMM Small CHMH CHHH dispersion spherical 197 BMDNLH Medium Fragmentary Non- Small High CHMM Medium CHMH CHHH dispersion spherical 198 BMDNLH Medium Fragmentary Non- Small High CHMM Large CHML CHHL dispersion spherical 199 BMDNML Medium Fragmentary Non- Medium Low CHLL Small CHLM CHMM dispersion spherical 200 BMDNML Medium Fragmentary Non- Medium Low CHLL Medium CHML CHMM dispersion spherical 201 BMDNML Medium Fragmentary Non- Medium Low CHLL Large CHML CHHL dispersion spherical 202 BMDNMM Medium Fragmentary Non- Medium Medium CHLM Small CHLH CHMH dispersion spherical 203 BMDNMM Medium Fragmentary Non- Medium Medium CHLM Medium CHLH CHMH dispersion spherical 204 BMDNMM Medium Fragmentary Non- Medium Medium CHLM Large CHML CHHL dispersion spherical 205 BMDNMH Medium Fragmentary Non- Medium High CHMH Small CHHH CHHH dispersion spherical 206 BMDNMH Medium Fragmentary Non- Medium High CHMH Medium CHHH CHLH dispersion spherical 207 BMDNMH Medium Fragmentary Non- Medium High CHMH Large CHMM CHML dispersion spherical 208 BMDNHL Medium Fragmentary Non- Large Low CHLL Small CHLM CHMM dispersion spherical 209 BMDNHL Medium Fragmentary Non- Large Low CHLL Medium CHLM CHMM dispersion spherical 210 BMDNHL Medium Fragmentary Non- Large Low CHLL Large CHML CHHL dispersion spherical 211 BMDNHM Medium Fragmentary Non- Large Medium CHML Small CHMM CHMH dispersion spherical 212 BMDNHM Medium Fragmentary Non- Large Medium CHML Medium CHMM CHHM dispersion spherical 213 BMDNHM Medium Fragmentary Non- Large Medium CHML Large CHLL CHHL dispersion spherical 214 BMDNHH Medium Fragmentary Non- Large High CHHL Small CHHM CHHH dispersion spherical 215 BMDNHH Medium Fragmentary Non- Large High CHHL Medium CHHM CHHH dispersion spherical 216 BMDNHH Medium Fragmentary Non- Large High CHHL Large CHML CHLL dispersion spherical 217 BMCSLL Medium Strip type Spherical Small Low CPLM Small CPLH CPMH 218 BMCSLL Medium Strip type Spherical Small Low CPLM Medium CPLH CPMH 219 BMCSLL Medium Strip type Spherical Small Low CPLM Large CPLL CPML 220 BMCSLM Medium Strip type Spherical Small Medium CPHM Small CPMH CPHH 221 BMCSLM Medium Strip type Spherical Small Medium CPHM Medium CPHH CPHH 222 BMCSLM Medium Strip type Spherical Small Medium CPHM Large CPML CPHL 223 BMCSLH Medium Strip type Spherical Small High CPMH Small CPHH CPHH 224 BMCSLH Medium Strip type Spherical Small High CPMH Medium CPHH CPHH 225 BMCSLH Medium Strip type Spherical Small High CPMH Large CPML CPMM 226 BMCSML Medium Strip type Spherical Medium Low CPLM Small CPLH CPMH 227 BMCSML Medium Strip type Spherical Medium Low CPLM Medium CPMM CPHM 228 BMCSML Medium Strip type Spherical Medium Low CPLM Large CPLL CPML 229 BMCSMM Medium Strip type Spherical Medium Medium CPMM Small CPMH CPHH 230 BMCSMM Medium Strip type Spherical Medium Medium CPMM Medium CPHM CPHH 231 BMCSMM Medium Strip type Spherical Medium Medium CPMM Large CPML CPLL 232 BMCSMH Medium Strip type Spherical Medium High CPHM Small CPHH CPMH 233 BMCSMH Medium Strip type Spherical Medium High CPHM Medium CPHH CPHH 234 BMCSMH Medium Strip type Spherical Medium High CPHM Large CPHL CPML 235 BMCSHL Medium Strip type Spherical Large Low CPLM Small CPLH CPMH 236 BMCSHL Medium Strip type Spherical Large Low CPLM Medium CPMM CPHM 237 BMCSHL Medium Strip type Spherical Large Low CPLM Large CPLL CPML 238 BMCSHM Medium Strip type Spherical Large Medium CPHL Small CPHM CPHH 239 BMCSHM Medium Strip type Spherical Large Medium CPHL Medium CPHM CPMH 240 BMCSHM Medium Strip type Spherical Large Medium CPHL Large CPML CPLL 241 BMCSHH Medium Strip type Spherical Large High CPHL Small CPHM CPMH 242 BMCSHH Medium Strip type Spherical Large High CPHL Medium CPHM CPMM 243 BMCSHH Medium Strip type Spherical Large High CPHL Large CPLL CPML 244 BMCNLL Medium Strip type Non- Small Low CPLL Small CPLM CPLH spherical 245 BMCNLL Medium Strip type Non- Small Low CPLL Medium CPML CPMM spherical 246 BMCNLL Medium Strip type Non- Small Low CPLL Large CPML CPHL spherical 247 BMCNLM Medium Strip type Non- Small Medium CPLM Small CPLH CPMH spherical 248 BMCNLM Medium Strip type Non- Small Medium CPLM Medium CPMM CPHM spherical 249 BMCNLM Medium Strip type Non- Small Medium CPLM Large CPLL CPML spherical 250 BMCNLH Medium Strip type Non- Small High CPLH Small CPLM CPMM spherical 251 BMCNLH Medium Strip type Non- Small High CPLH Medium CPMH CPHM spherical 252 BMCNLH Medium Strip type Non- Small High CPLH Large CPMM CPHL spherical 253 BMCNML Medium Strip type Non- Medium Low CPLL Small CPLM CPLH spherical 254 BMCNML Medium Strip type Non- Medium Low CPLL Medium CPLM CPMM spherical 255 BMCNML Medium Strip type Non- Medium Low CPLL Large CPML CPHL spherical 256 BMCNMM Medium Strip type Non- Medium Medium CPLM Small CPLH CPMH spherical 257 BMCNMM Medium Strip type Non- Medium Medium CPLM Medium CPMM CPHM spherical 258 BMCNMM Medium Strip type Non- Medium Medium CPLM Large CPLL CPML spherical 259 BMCNMH Medium Strip type Non- Medium High CPLH Small CPMH CPHH spherical 260 BMCNMH Medium Strip type Non- Medium High CPLH Medium CPMH CPHH spherical 261 BMCNMH Medium Strip type Non- Medium High CPLH Large CPLM CPML spherical 262 BMCNHL Medium Strip type Non- Large Low CPLL Small CPLM CPMH spherical 263 BMCNHL Medium Strip type Non- Large Low CPLL Medium CPML CPHL spherical 264 BMCNHL Medium Strip type Non- Large Low CPLL Large CPML CPHL spherical 265 BMCNHM Medium Strip type Non- Large Medium CPLM Small CPLH CPMH spherical 266 BMCNHM Medium Strip type Non- Large Medium CPLM Medium CPMM CPHM spherical 267 BMCNHM Medium Strip type Non- Large Medium CPLM Large CPLL CPML spherical 268 BMCNHH Medium Strip type Non- Large High CPLH Small CPMH CPHH spherical 269 BMCNHH Medium Strip type Non- Large High CPLH Medium CPMH CPHH spherical 270 BMCNHH Medium Strip type Non- Large High CPLH Large CPMM CPHM spherical 271 BMGSLL Medium Dense cover Spherical Small Low CFLH Small CFMH CFHH 272 BMGSLL Medium Dense cover Spherical Small Low CFLH Medium CFMH CFHH 273 BMGSLL Medium Dense cover Spherical Small Low CFLH Large CFML CFMM 274 BMGSLM Medium Dense cover Spherical Small Medium CFMH Small CFHH CFHH 275 BMGSLM Medium Dense cover Spherical Small Medium CFMH Medium CFHH CFHH 276 BMGSLM Medium Dense cover Spherical Small Medium CFMH Large CFML CFHM 277 BMGSLH Medium Dense cover Spherical Small High CFHH Small CFHH CFHH 278 BMGSLH Medium Dense cover Spherical Small High CFHH Medium CFHH CFHH 279 BMGSLH Medium Dense cover Spherical Small High CFHH Large CFHM CFHL 280 BMGSML Medium Dense cover Spherical Medium Low CFLM Small CFLH CFMH 281 BMGSML Medium Dense cover Spherical Medium Low CFLM Medium CFMM CFHM 282 BMGSML Medium Dense cover Spherical Medium Low CFLM Large CFLL CFML 283 BMGSMM Medium Dense cover Spherical Medium Medium CFMM Small CFMH CFMH 284 BMGSMM Medium Dense cover Spherical Medium Medium CFMM Medium CFHM CFHH 285 BMGSMM Medium Dense cover Spherical Medium Medium CFMM Large CFML CFHL 286 BMGSMH Medium Dense cover Spherical Medium High CFHM Small CFHH CFHH 287 BMGSMH Medium Dense cover Spherical Medium High CFHM Medium CFHH CFHH 288 BMGSMH Medium Dense cover Spherical Medium High CFHM Large CFHL CFML 289 BMGSHL Medium Dense cover Spherical Large Low CFLM Small CFLH CFMH 290 BMGSHL Medium Dense cover Spherical Large Low CFLM Medium CFMM CFMH 291 BMGSHL Medium Dense cover Spherical Large Low CFLM Large CFML CFHL 292 BMGSHM Medium Dense cover Spherical Large Medium CFHL Small CFHM CFHM 293 BMGSHM Medium Dense cover Spherical Large Medium CFHL Medium CFHM CFHM 294 BMGSHM Medium Dense cover Spherical Large Medium CFHL Large CFHM CFHM 295 BMGSHH Medium Dense cover Spherical Large High CFHL Small CFHM CFHM 296 BMGSHH Medium Dense cover Spherical Large High CFHL Medium CFHM CFHM 297 BMGSHH Medium Dense cover Spherical Large High CFHL Large CFML CFML 298 BMGNLL Medium Dense cover Non- Small Low CFLL Small CFLM CFMM spherical 299 BMGNLL Medium Dense cover Non- Small Low CFLL Medium CFML CFHL spherical 300 BMGNLL Medium Dense cover Non- Small Low CFLL Large CFML CFHL spherical 301 BMGNLM Medium Dense cover Non- Small Medium CFLM Small CFLH CFMH spherical 302 BMGNLM Medium Dense cover Non- Small Medium CFLM Medium CFMM CFMH spherical 303 BMGNLM Medium Dense cover Non- Small Medium CFLM Large CFML CFHL spherical 304 BMGNLH Medium Dense cover Non- Small High CFLH Small CFMH CFHH spherical 305 BMGNLH Medium Dense cover Non- Small High CFLH Medium CFMH CFHH spherical 306 BMGNLH Medium Dense cover Non- Small High CFLH Large CFLM CFMM spherical 307 BMGNML Medium Dense cover Non- Medium Low CFLL Small CFLH CFLM spherical 308 BMGNML Medium Dense cover Non- Medium Low CFLL Medium CFML CFMM spherical 309 BMGNML Medium Dense cover Non- Medium Low CFLL Large CFML CFML spherical 310 BMGNMM Medium Dense cover Non- Medium Medium CFLM Small CFLH CFMM spherical 311 BMGNMM Medium Dense cover Non- Medium Medium CFLM Medium CFMM CFHM spherical 312 BMGNMM Medium Dense cover Non- Medium Medium CFLM Large CFMM CFML spherical 313 BMGNMH Medium Dense cover Non- Medium High CFLH Small CFMH CFHH spherical 314 BMGNMH Medium Dense cover Non- Medium High CFLH Medium CFMH CFMH spherical 315 BMGNMH Medium Dense cover Non- Medium High CFLH Large CFMM CFHM spherical 316 BMGNHL Medium Dense cover Non- Large Low CFLL Small CFLM CFMM spherical 317 BMGNHL Medium Dense cover Non- Large Low CFLL Medium CFML CFMM spherical 318 BMGNHL Medium Dense cover Non- Large Low CFLL Large CFML CFHL spherical 319 BMGNHM Medium Dense cover Non- Large Medium CFLM Small CFLH CFHH spherical 320 BMGNHM Medium Dense cover Non- Large Medium CFLM Medium CFMM CHMM spherical 321 BMGNHM Medium Dense cover Non- Large Medium CFLM Large CFHL CFHM spherical 322 BMGNHH Medium Dense cover Non- Large High CFLH Small CFMH CFHH spherical 323 BMGNHH Medium Dense cover Non- Large High CFLH Medium CFMH CFHH spherical 324 BMGNHH Medium Dense cover Non- Large High CFLH Large CFMM CFHM spherical 325 BHDSLL High Fragmentary Spherical Small Low CHLM Small CHLH CFMM dispersion 326 BHDSLL High Fragmentary Spherical Small Low CHLM Medium CHMM CHMH dispersion 327 BHDSLL High Fragmentary Spherical Small Low CHLM Large CHMM CHHL dispersion 328 BHDSLM High Fragmentary Spherical Small Medium CHMM Small CHMH CHMH dispersion 329 BHDSLM High Fragmentary Spherical Small Medium CHMM Medium CHHM CHMH dispersion 330 BHDSLM High Fragmentary Spherical Small Medium CHMM Large CHHM CHHL dispersion 331 BHDSLH High Fragmentary Spherical Small High CHHM Small CHHH CHHH dispersion 332 BHDSLH High Fragmentary Spherical Small High CHHM Medium CHHH CHHH dispersion 333 BHDSLH High Fragmentary Spherical Small High CHHM Large CHHL CHMM dispersion 334 BHDSML High Fragmentary Spherical Medium Low CHLM Small CHLH CHMM dispersion 335 BHDSML High Fragmentary Spherical Medium Low CHLM Medium CHMM CHHM dispersion 336 BHDSML High Fragmentary Spherical Medium Low CHLM Large CHMM CHLL dispersion 337 BHDSMM High Fragmentary Spherical Medium Medium CHMM Small CHMH CHHH dispersion 338 BHDSMM High Fragmentary Spherical Medium Medium CHMM Medium CHHM CHMH dispersion 339 BHDSMM High Fragmentary Spherical Medium Medium CHMM Large CHML CHHL dispersion 340 BHDSMH High Fragmentary Spherical Medium High CHHM Small CHHH CHHH dispersion 341 BHDSMH High Fragmentary Spherical Medium High CHHM Medium CHHH CHHH dispersion 342 BHDSMH High Fragmentary Spherical Medium High CHHM Large CHHL CHML dispersion 343 BHDSHL High Fragmentary Spherical Large Low CHLL Small CHLM CHLH dispersion 344 BHDSHL High Fragmentary Spherical Large Low CHLL Medium CHML CHMM dispersion 345 BHDSHL High Fragmentary Spherical Large Low CHLL Large CHML CHHL dispersion 346 BHDSHM High Fragmentary Spherical Large Medium CHML Small CHMM CHMH dispersion 347 BHDSHM High Fragmentary Spherical Large Medium CHML Medium CHHL CHHM dispersion 348 BHDSHM High Fragmentary Spherical Large Medium CHML Large CHHL CHHL dispersion 349 BHDSHH High Fragmentary Spherical Large High CHHL Small CHHM CHHH dispersion 350 BHDSHH High Fragmentary Spherical Large High CHHL Medium CHHM CHHM dispersion 351 BHDSHH High Fragmentary Spherical Large High CHHL Large CHML CHLL dispersion 352 BHDNLL High Fragmentary Non- Small Low CHLL Small CHLM CHLH dispersion spherical 353 BHDNLL High Fragmentary Non- Small Low CHLL Medium CHML CHMM dispersion spherical 354 BHDNLL High Fragmentary Non- Small Low CHLL Large CHML CHHL dispersion spherical 355 BHDNLM High Fragmentary Non- Small Medium CHML Small CHMM CHMH dispersion spherical 356 BHDNLM High Fragmentary Non- Small Medium CHML Medium CHHL CHHM dispersion spherical 357 BHDNLM High Fragmentary Non- Small Medium CHML Large CHHL CHHL dispersion spherical 358 BHDNLH High Fragmentary Non- Small High CHMM Small CHHM CHHH dispersion spherical 359 BHDNLH High Fragmentary Non- Small High CHMM Medium CHHM CHHM dispersion spherical 360 BHDNLH High Fragmentary Non- Small High CHMM Large CHML CHLL dispersion spherical 361 BHDNML High Fragmentary Non- Medium Low CHLL Small CHLH CHLM dispersion spherical 362 BHDNML High Fragmentary Non- Medium Low CHLL Medium CHML CHMM dispersion spherical 363 BHDNML High Fragmentary Non- Medium Low CHLL Large CHML CHHL dispersion spherical 364 BHDNMM High Fragmentary Non- Medium Medium CHLM Small CHLH CHMH dispersion spherical 365 BHDNMM High Fragmentary Non- Medium Medium CHLM Medium CHMM CHHM dispersion spherical 366 BHDNMM High Fragmentary Non- Medium Medium CHLM Large CHMM CHHM dispersion spherical 367 BHDNMH High Fragmentary Non- Medium High CHMH Small CHHH CHHH dispersion spherical 368 BHDNMH High Fragmentary Non- Medium High CHMH Medium CHHH CHHH dispersion spherical 369 BHDNMH High Fragmentary Non- Medium High CHMH Large CHHM CHHL dispersion spherical 370 BHDNHL High Fragmentary Non- Large Low CHLL Small CHLM CHLH dispersion spherical 371 BHDNHL High Fragmentary Non- Large Low CHLL Medium CHML CHMM dispersion spherical 372 BHDNHL High Fragmentary Non- Large Low CHLL Large CHML CHHL dispersion spherical 373 BHDNHM High Fragmentary Non- Large Medium CHML Small CHMM CHMH dispersion spherical 374 BHDNHM High Fragmentary Non- Large Medium CHML Medium CHHL CHHM dispersion spherical 375 BHDNHM High Fragmentary Non- Large Medium CHML Large CHHL CHMM dispersion spherical 376 BHDNHH High Fragmentary Non- Large High CHHL Small CHHM CHHH dispersion spherical 377 BHDNHH High Fragmentary Non- Large High CHHL Medium CHHM CHHM dispersion spherical 378 BHDNHH High Fragmentary Non- Large High CHHL Large CHMH CHHL dispersion spherical 379 BHCSLL High Strip type Spherical Small Low CPLM Small CPLH CPMH 380 BHCSLL High Strip type Spherical Small Low CPLM Medium CPMM CPLH 381 BHCSLL High Strip type Spherical Small Low CPLM Large CPML CPMM 382 BHCSLM High Strip type Spherical Small Medium CPHM Small CPHH CPHH 383 BHCSLM High Strip type Spherical Small Medium CPHM Medium CPHH CPMH 384 BHCSLM High Strip type Spherical Small Medium CPHM Large CPHL CPHL 385 BHCSLH High Strip type Spherical Small High CPMH Small CPHH CPHH 386 BHCSLH High Strip type Spherical Small High CPMH Medium CPHH CPHH 387 BHCSLH High Strip type Spherical Small High CPMH Large CPML CPMM 388 BHCSML High Strip type Spherical Medium Low CPLM Small CPLH CPMH 389 BHCSML High Strip type Spherical Medium Low CPLM Medium CPMM CPHM 390 BHCSML High Strip type Spherical Medium Low CPLM Large CPMM CPML 391 BHCSMM High Strip type Spherical Medium Medium CPMM Small CPMH CPHH 392 BHCSMM High Strip type Spherical Medium Medium CPMM Medium CPMH CPHM 393 BHCSMM High Strip type Spherical Medium Medium CPMM Large CPML CPHL 394 BHCSMH High Strip type Spherical Medium High CPHM Small CPHH CPMH 395 BHCSMH High Strip type Spherical Medium High CPHM Medium CPHH CPMH 396 BHCSMH High Strip type Spherical Medium High CPHM Large CPHL CPML 397 BHCSHL High Strip type Spherical Large Low CPLM Small CPLH CPMH 398 BHCSHL High Strip type Spherical Large Low CPLM Medium CPLH CPMH 399 BHCSHL High Strip type Spherical Large Low CPLM Large CPML CPMM 400 BHCSHM High Strip type Spherical Large Medium CPHL Small CPHM CPHH 401 BHCSHM High Strip type Spherical Large Medium CPHL Medium CPHM CPHL 402 BHCSHM High Strip type Spherical Large Medium CPHL Large CPLL CPML 403 BHCSHH High Strip type Spherical Large High CPHL Small CPHM CPHH 404 BHCSHH High Strip type Spherical Large High CPHL Medium CPHM CPMM 405 BHCSHH High Strip type Spherical Large High CPHL Large CPML CPMM 406 BHCNLL High Strip type Non- Small Low CPLL Small CPLM CPLH spherical 407 BHCNLL High Strip type Non- Small Low CPLL Medium CPML CPHL spherical 408 BHCNLL High Strip type Non- Small Low CPLL Large CPML CPHL spherical 409 BHCNLM High Strip type Non- Small Medium CPLM Small CPLH CPMH spherical 410 BHCNLM High Strip type Non- Small Medium CPLM Medium CPMM CPHM spherical 411 BHCNLM High Strip type Non- Small Medium CPLM Large CPMM CPML spherical 412 BHCNLH High Strip type Non- Small High CPLH Small CPMH CPHH spherical 413 BHCNLH High Strip type Non- Small High CPLH Medium CPMH CPHH spherical 414 BHCNLH High Strip type Non- Small High CPLH Large CPMM CPHL spherical 415 BHCNML High Strip type Non- Medium Low CPLL Small CPLM CPLH spherical 416 BHCNML High Strip type Non- Medium Low CPLL Medium CPML CPMM spherical 417 BHCNML High Strip type Non- Medium Low CPLL Large CPML CPHL spherical 418 BHCNMM High Strip type Non- Medium Medium CPLM Small CPLH CPMH spherical 419 BHCNMM High Strip type Non- Medium Medium CPLM Medium CPMM CPHM spherical 420 BHCNMM High Strip type Non- Medium Medium CPLM Large CPLL CPML spherical 421 BHCNMH High Strip type Non- Medium High CPLH Small CPMH CPHH spherical 422 BHCNMH High Strip type Non- Medium High CPLH Medium CPMH CPHH spherical 423 BHCNMH High Strip type Non- Medium High CPLH Large CPML CPHL spherical 424 BHCNHL High Strip type Non- Large Low CPLL Small CPLM CPMM spherical 425 BHCNHL High Strip type Non- Large Low CPLL Medium CPMM CPHM spherical 426 BHCNHL High Strip type Non- Large Low CPLL Large CPML CPHL spherical 427 BHCNHM High Strip type Non- Large Medium CPLM Small CPLH CPMM spherical 428 BHCNHM High Strip type Non- Large Medium CPLM Medium CPMM CPMH spherical 429 BHCNHM High Strip type Non- Large Medium CPLM Large CPLL CPML spherical 430 BHCNHH High Strip type Non- Large High CPLH Small CPMH CPHH spherical 431 BHCNHH High Strip type Non- Large High CPLH Medium CPMH CPHH spherical 432 BHCNHH High Strip type Non- Large High CPLH Large CPML CPMM spherical 433 BHGSLL High Dense cover Spherical Small Low CFLH Small CFMH CFHH 434 BHGSLL High Dense cover Spherical Small Low CFLH Medium CFMH CFHH 435 BHGSLL High Dense cover Spherical Small Low CFLH Large CFML CFHL 436 BHGSLM High Dense cover Spherical Small Medium CFMH Small CFHH CFHH 437 BHGSLM High Dense cover Spherical Small Medium CFMH Medium CFHM CFHH 438 BHGSLM High Dense cover Spherical Small Medium CFMH Large CFLM CFMM 439 BHGSLH High Dense cover Spherical Small High CFHH Small CFHH CFHH 440 BHGSLH High Dense cover Spherical Small High CFHH Medium CFMH CFMH 441 BHGSLH High Dense cover Spherical Small High CFHH Large CFML CFMM 442 BHGSML High Dense cover Spherical Medium Low CFLM Small CFLH CFMH 443 BHGSML High Dense cover Spherical Medium Low CFLM Medium CFMM CFHM 444 BHGSML High Dense cover Spherical Medium Low CFLM Large CFHL CFML 445 BHGSMM High Dense cover Spherical Medium Medium CFMM Small CFMH CFHH 446 BHGSMM High Dense cover Spherical Medium Medium CFMM Medium CFHM CFMH 447 BHGSMM High Dense cover Spherical Medium Medium CFMM Large CFML CFLL 448 BHGSMH High Dense cover Spherical Medium High CFHM Small CFHH CFMH 449 BHGSMH High Dense cover Spherical Medium High CFHM Medium CFMH CFHH 450 BHGSMH High Dense cover Spherical Medium High CFHM Large CFML CFHL 451 BHGSHL High Dense cover Spherical Large Low CFLM Small CFLH CFMH 452 BHGSHL High Dense cover Spherical Large Low CFLM Medium CFMM CFHM 453 BHGSHL High Dense cover Spherical Large Low CFLM Large CFMM CFHL 454 BHGSHM High Dense cover Spherical Large Medium CFHL Small CFMH CFHH 455 BHGSHM High Dense cover Spherical Large Medium CFHL Medium CFHM CFHH 456 BHGSHM High Dense cover Spherical Large Medium CFHL Large CFML CFLM 457 BHGSHH High Dense cover Spherical Large High CFHL Small CFHM CFHH 458 BHGSHH High Dense cover Spherical Large High CFHL Medium CFHM CFMM 459 BHGSHH High Dense cover Spherical Large High CFHL Large CFML CFLL 460 BHGNLL High Dense cover Non- Small Low CFLL Small CFLM CFMM spherical 461 BHGNLL High Dense cover Non- Small Low CFLL Medium CFML CFMM spherical 462 BHGNLL High Dense cover Non- Small Low CFLL Large CFML CFHL spherical 463 BHGNLM High Dense cover Non- Small Medium CFLM Small CFLH CFMM spherical 464 BHGNLM High Dense cover Non- Small Medium CFLM Medium CFMM CFHM spherical 465 BHGNLM High Dense cover Non- Small Medium CFLM Large CFLL CFML spherical 466 BHGNLH High Dense cover Non- Small High CFLH Small CFMH CFHH spherical 467 BHGNLH High Dense cover Non- Small High CFLH Medium CFMH CFMM spherical 468 BHGNLH High Dense cover Non- Small High CFLH Large CFML CFHL spherical 469 BHGNML High Dense cover Non- Medium Low CFLL Small CFLM CFMM spherical 470 BHGNML High Dense cover Non- Medium Low CFLL Medium CFML CFMM spherical 471 BHGNML High Dense cover Non- Medium Low CFLL Large CFML CFHL spherical 472 BHGNMM High Dense cover Non- Medium Medium CFLM Small CFLH CFMH spherical 473 BHGNMM High Dense cover Non- Medium Medium CFLM Medium CFMM CFMH spherical 474 BHGNMM High Dense cover Non- Medium Medium CFLM Large CFML CFHL spherical 475 BHGNMH High Dense cover Non- Medium High CFLH Small CFMH CFHH spherical 476 BHGNMH High Dense cover Non- Medium High CFLH Medium CFMH CFHH spherical 477 BHGNMH High Dense cover Non- Medium High CFLH Large CFMM CFHM spherical 478 BHGNHL High Dense cover Non- Large Low CFLL Small CFLM CFMM spherical 479 BHGNHL High Dense cover Non- Large Low CFLL Medium CFML CFMM spherical 480 BHGNHL High Dense cover Non- Large Low CFLL Large CFML CFML spherical 481 BHGNHM High Dense cover Non- Large Medium CFLM Small CFMH CFHH spherical 482 BHGNHM High Dense cover Non- Large Medium CFLM Medium CFMM CFHM spherical 483 BHGNHM High Dense cover Non- Large Medium CFLM Large CFML CFHL spherical 484 BHGNHH High Dense cover Non- Large High CFLH Small CFMH CFHH spherical 485 BHGNHH High Dense cover Non- Large High CFLH Medium CFMH CFHH spherical 486 BHGNHH High Dense cover Non- Large High CFLH Large CFMM CFML spherical Note: The initial operation solution is the proposed operation solution which is given according to site harmful algal bloom features. After operation for 20-30 min, the grain size of the flocculate and the fluorescence value of the chlorophyll in vivo within 1 m from surface layer of the water body in the operation site are observed. If the fluorescence value of chlorophyll is reduced by above 15%, it is recommended to continue the operation in accordance with the site operation solution; and if the fluorescence value of chlorophyll is reduced by under 15%, it is considered to adjust the operation solution. When the solution is adjusted, the operation effect is firstly graded according to the observed grain size features of the flocculate (see Table 1); and then adjustable operation solutions are queried from the original harmful algal bloom code and corresponding flocculate feature lines in the table.

TABLE 3 Operation Solution for Sprinkling Modified Clay Sprinkling Sprinkling Codes Sprinkling Manner Strength Concentration CPLL Pursuing and raining Low Low type frequency CPLM Pursuing and raining Low Medium type frequency CPLH Pursuing and raining Low High type frequency CPML Pursuing and raining Medium Low type frequency CPMM Pursuing and raining Medium Medium type frequency CPMH Pursuing and raining Medium High type frequency CPHL Pursuing and raining High Low type frequency CPHM Pursuing and raining High Medium type frequency CPHH Pursuing and raining High High type frequency CHLL Field sweeping and Low Low raining type frequency CHLM Field sweeping and Low Medium raining type frequency CHLH Field sweeping and Low High raining type frequency CHML Field sweeping and Medium Low raining type frequency CHMM Field sweeping and Medium Medium raining type frequency CHMH Field sweeping and Medium High raining type frequency CHHL Field sweeping and High Low raining type frequency CHHM Field sweeping and High Medium raining type frequency CHHH Field sweeping and High High raining type frequency CFLL Local centralizing and Low Low raining type frequency CFLM Local centralizing and Low Medium raining type frequency CFLH Local centralizing and Low High raining type frequency CFML Local centralizing and Medium Low raining type frequency CFMM Local centralizing and Medium Medium raining type frequency CFMH Local centralizing and Medium High raining type frequency CFHL Local centralizing and High Low raining type frequency CFHM Local centralizing and High Medium raining type frequency CFHH Local centralizing and High High raining type frequency

Sprinkling strength means the number of times of repeatedly sprinkling modified clay on the same water surface in unit time. Low frequency is less than 2 times/hour, medium frequency is 2-5 times/hour and high frequency is greater than 5 times/hour.

When the harmful algal bloom is treated by the modified clay method, generally the modified clay material is mixed with seawater in a container in advance to form thin pulp with a certain concentration, and then is sprinkled on the surface of the water body of the harmful algal bloom. Sprinkling concentration means the concentration of the modified clay material premixed with seawater. Low concentration is less than 100 g/L, medium concentration is 100-200 g/L and high concentration is greater than 200 g/L.

The present invention has the following advantages:

A screening method for operation solutions of eliminating harmful algal blooms through optimized utilization of a modified clay method is provided. The method proposes an optimized solution for sprinkling operation of modified clay after programmed decisions of an expert system for guiding the operation of eliminating harmful algal bloom using modified clay based on the features of the harmful algal bloom organisms and modified clay flocculates within the water body observed in site in real time, so as to improve refinement and programming during site implementation of treating the harmful algal bloom using the modified clay method, facilitating the increase of field operation efficiency of treating the harmful algal bloom using the modified clay method and providing a foundation for the development of harmful algal bloom prevention and treatment projects towards automatic construction.

Of course, the implementation method in the present invention is not only suitable for treating the harmful algal bloom using the modified clay method, but also suitable for treating the harmful algal bloom using unmodified natural clay, so as to effectively enhance energy efficiency of treating the harmful algal bloom using the clay materials.

DESCRIPTION OF DRAWINGS

FIG. 1 is a structural diagram of guiding operation of eliminating harmful algal blooms based on an expert system provided in the embodiments of the present invention.

DETAILED DESCRIPTION

To make the purpose, the technical solution and the advantages of the present invention more clear, the present invention will be further described below in details through embodiments. It should be understood that concrete embodiments described for this purpose are only used to explain the present invention, not to limit the present invention.

The present invention increases algae removal efficiency of the modified clay in engineering construction through optimized utilization of the site implementation effect of eliminating the harmful algal bloom by a modified clay method. In view of the problems of work target of elimination operation, extensive use amount, etc. due to lack of a refined operation method in the existing engineering construction, the present invention provides an implementation method for eliminating harmful algal blooms through an efficient optimized modified clay method. The method proposes an optimized operation solution through programmed decisions of the expert system based on a harmful algal bloom prevention and treatment expert system having intelligent information processing capability in accordance with the feature index values of the harmful algal bloom organisms and modified clay flocculates in the water body acquired in site in real time, and adjusts the operation solution in real time according to the change of the site feature index values. The method can realize refinement and programming during site implementation of treating the harmful algal bloom using the modified clay method, and facilitates the increase of field operation efficiency of treating the harmful algal bloom using the modified clay method.

EMBODIMENTS

Heterosigma carterae of harmful algal bloom is a common harmful algal bloom organism in offshore breeding areas in China. It is found through microscopy with a microscope that cells are oval. The individual has a length of about 8-25 μm and a width of about 6-15 μm through determination with a fluorescence method, a counting method, a spectrophotometric method and chromatography. Heterosigma carterae has strong buoyant capability and often spreads over the whole sea area when the harmful algal bloom breaks out. The heterosigma carterae harmful algal bloom breaks out in a certain offshore bay in Qingdao. The fluorescence value of chlorophyll in vivo in the water body is monitored by an online in vivo fluorimeter in site, which is greater than 30 μg/L. By referring to Table 1, grading and quantifying codes of the harmful algal bloom in this area are judged as follows: serious harmful algal bloom (H), fragmentary dispersion (D), spherical cell monomer (S), small cell (L), and strong buoyant capability (H). Letter B is added before each index. The code of the heterosigma carterae harmful algal bloom is obtained as BHDSLH in accordance with the above order. A recommended elimination solution with the harmful algal bloom code of BHDSLH is queried in Table 2 as CHHM, with the number of 332. The operation solution for sprinkling modified clay of CHHM is queried in Table 3 as follows: the sprinkling manner is field sweeping and raining type; sprinkling strength is high frequency; sprinkling concentration is medium; and the solution can be adopted in site operation.

After site construction for 30 minutes, the median particle size (D50) of flocculate is measured as 45 um within 1 meter on the surface layer of the working region with an underwater laser light scattering particle detector. If the fluorescence value of the chlorophyll in vivo in the water body is reduced to a value within 25 μg/L by above 15%, the operation can be continued in accordance with the operation solution. But if the fluorescence value of the chlorophyll in vivo in the water body is still greater than 25 μg/L and is reduced by below 15%, it can be preliminarily judged that the used operation solution is not ideal in the elimination effect and needs to be adjusted in time. By referring to Table 1 for the grain size features of modified clay flocculates in which the flocculate is assessed as medium (M), and Table 3 in which the harmful algal bloom code is BHDSLH and the flocculate grade is M line, it can be queried that the recommended operation solution is adjusted as CHHH. The solution has a sprinkling manner of field sweeping and raining type, and high frequency sprinkling strength and high sprinkling concentration. Field operation can be adjusted to this operation manner.

Through site online observation and expert system decisions for guiding the operation of eliminating the harmful algal bloom using modified clay, a scientific operation solution is provided rapidly for the site elimination operation of the harmful algal bloom, and can be optimized in time according to the site implementation effect. The operation solution is especially consistent with requirements for quick response and quick effect of disaster emergency control. In addition, programming operation for treating the harmful algal bloom using the modified clay method is initiated, providing a foundation for the development of harmful algal bloom prevention and treatment projects towards automatic construction. 

We claim:
 1. An implementation method for eliminating harmful algal blooms through optimized utilization of a modified clay method, comprising: 1) building a real-time state index of algae and floc particles formed between algae and modified clays and a standardized value grading system for HABs treatment in accordance with the features of blooms and flocculation monitored in field; 2) obtaining the corresponding grade code which denotes the field algal bloom state by checking a standardized value grading system according to the state index values; 3) comparing the above grade code with an expert system to obtain an optimized operation solution for HABs treatment with the modified clays.
 2. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 1, wherein after 20-30 min when a field operation is implemented in accordance with the introduced solution obtained by above programme, the chlorophyll fluorescence and the floc size in the treated water are determined; the preliminary effectiveness of treatment is judged according to the change of the chlorophyll fluorescence; if the chlorophyll fluorescence value is reduced by more than 15%, the field operation is continuously implemented in accordance with the introduced operation solution until the removal efficiency is less than 15%; if the chlorophyll fluorescence value is reduced by less than 15%, it means that the introduced operation solution is not ideally effective and a new solution should be chosen according to the real-time observation result using the above expert system again.
 3. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 1, wherein the real-time state index and the standardized value grading system are designed by grading the index values after calculating the values of all indices of the HABs and the modified clay flocs in water.
 4. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 1, wherein the HAB indices comprise seriousness, distribution characteristics, cell morphology, cell size, and motion capability of bloomed organisms; and the feature of the modified clay flocs is represented by the grain size of the modified clay flocs.
 5. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 1, wherein the order of corresponding grade codes is consistent with the order of the determined feature indexes of the HAB and the modified clay flocs.
 6. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 3, wherein the HAB seriousness is graded into low, medium and high and their corresponding codes are L, M and H, wherein low seriousness means that the chl.a concentration given by the fluorescence of the bloomed water is less than 15 μg/L; medium seriousness means that the chl.a concentration given by the fluorescence of the bloomed water is 15-30 μg/L; high seriousness means that the chl.a concentration given by the fluorescence of the water is greater than 30 μg/L; the HABs distribution characteristics are classified into three types, i.e. fragmentary dispersion, strip type, dense cover, with corresponding codes of D, C and G respectively; HABs usually behave differently according to the local water current or tide; the cell morphology of the bloomed organisms are divided into spherical or non-spherical forms, with the corresponding codes of S and N; the spherical or subsphaeroidal shape is dominant in bloomed species; if there are hard bulges or subsidiary organelle on the cell outside but their sizes to the cell in diameter is less than ½, the organism is thought as sphere; otherwise, the organism is thought as non-spherical cell; the cell sizes of algae are divided into small, medium and large, and corresponding codes are L, M and N, wherein small size means that the cell diameter of the organism is less than 15 μm; medium size means that the cell diameter of the organism is 15-100 μm; and large size means that the cell diameter of the organism is greater than 100 μm; the motion capability of the organisms is divided into low, medium and high, and corresponding codes are L, M and H, wherein low capability means that the organism does not have motion capability and is suspended under the action of the water flow, etc.; medium capability means that the organism does not have motion capability but is suspended due to phototaxis or has weak buoyant capability; high capability means that the harmful algal bloom organism has strong buoyant capability; high capability means that the harmful algal bloom organism has strong buoyant capability; the grain sizes of the modified clay flocs are divided into small, medium and large, and corresponding codes are L, M and H, wherein small grain size means that the median particle size (D50) is less than the cell diameter of the organism; medium grain size means that the median particle size (D50) is 1-5 times of the cell diameter of the organism; and large grain size means that the median particle size (D50) is more than 5 times of the cell diameter of the organism.
 7. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 1, wherein the expert system is used for acquiring the operation solution including grade codes and corresponding feature grades of the harmful algal bloom organisms and corresponding operation solution code.
 8. The implementation method for eliminating the harmful algal blooms through optimized utilization of the modified clay method according to claim 7, wherein the operation solution code corresponds to the concrete operation solution for sprinkling the modified clay; the operation solution is composed of sprinkling modes, and density and frequency for sprinkling the modified clay, wherein the sprinkling modes comprise raining type, pouring type or ploughing type; the sprinkling density is a proportion of the modified clay powder with seawater in a slurry which is selected in field and obtained by premixing the powder with seawater before sprinkling onto the bloomed water surface; and the sprinkling frequency means duration time, an interval and sprinkling number of times when operation at the same site. 